KR102192625B1 - Coupling assembly for electronic components cooling device - Google Patents

Abstract

A first embodiment of an integrated booster for an ultrasonic vibrator module according to the present invention comprises: a first body on a vibrator side; a second body on a horn side having a diameter smaller than that of the first body; a support protruding along the periphery of the boundary part of the first and second bodies; and a flange and a packing coupled along the periphery of the upper surface of the support. The integrated booster for an ultrasonic vibrator module includes a support coupling unit having a diameter larger than that of the supporter along the periphery of the upper surface of the support and integrally coupled to the support in a state that the flange and the packing are removed.

Description

All-in-one booster for ultrasonic vibrator module {COUPLING ASSEMBLY FOR ELECTRONIC COMPONENTS COOLING DEVICE}

The present invention relates to an integrated booster for an ultrasonic vibrator module, and more specifically, without using a flange and packing widely used as a fastening means for coupling a vibrator and a horn to a booster, which is a component of an ultrasonic vibrator module that generates ultrasonic vibration. It relates to a one-body type, that is, an integrated booster that can be coupled with a vibrator and a horn in an integrated structure.

The ultrasonic vibrator module is a device that can be used for various purposes for sealing, punching, and cutting a workpiece through a vibrator that generates ultrasonic waves, or providing cleaning power to a cleaner.

Such an ultrasonic vibrator module has various structures and types, but a structure including a vibrator, a booster, and a horn is widely used.

1 is an exploded perspective view showing a detailed structure of a conventional ultrasonic vibrator module, and FIG. 2 is an exploded perspective view and a cross-sectional view showing the detailed structure of a booster in FIG. 1.

As can be seen from FIG. 1, a known ultrasonic vibrator module is a piezoelectric element with a vibrator (ultrasonic vibrator) 10 that converts electrical energy into ultrasonic vibration energy, and a booster that is combined with the vibrator 10 to amplify ultrasonic vibration energy. It consists of a horn 20 that is combined with the booster 100 and transmits ultrasonic vibration energy to the processing target (or cleaning target).

At this time, the vibrator 10 has a structure in which a piezoelectric element is inserted between a pair of metal blocks and a metal block is tightly tightened through a plurality of bolts and packings, which is also called a bolt-tight ranjuban type vibrator, and at this time, a pair of metal blocks Among them, the metal block on the side of the booster 100 is referred to as the front mass 11.

In addition, the booster 100 is located between the vibrator 10 and the horn 20, in other words, the horn 20 is coupled to the upper side of the booster 100 based on FIG. 1 and the vibrator 10 is located at the lower side of the booster 100. ), it can be seen that the front mass 11 of the vibrator 10 is specifically coupled. In addition, the booster 100 has a cylindrical structure that differs in diameter from one end to the other when extending from the other end along the height direction, that is, in many cases, it is composed of the first and second bodies 110 and 120, and the convenience of coupling with the wall of the mounting target In order to provide a tray, it is often provided with a support 130 extending along the circumference by protruding to have a larger diameter than other portions.

As can be seen from FIG. 1, the known booster 100 is a flange 1 itself or a flange (1) itself or a flange (with a support 130) to be coupled to the wall of a mounting object (washer, cutter, polishing machine, etc.) on which the vibrator module is mounted. Combine 1) and packing (2).

When the mounting target is an ultrasonic dishwasher, for example, a booster 100 having a support 130 at a central portion may have the same diameter as one end of the booster 100 on the wall of the tank of the ultrasonic dishwasher. When inserted into a similar through-hole, the booster 100 is caught without exiting the through-hole by the supporter 130 having a larger diameter than the through-hole, and in this state, the flange (1) on each of the upper and lower surfaces of the supporter 130 After attaching and combining the and packing (2), the fixed connection is finished by fastening it to the wall through fasteners such as bolts.

This flange (1) is not necessarily used only for coupling with the mounting object, but because of its own protruding structure, it wraps around the support 130 for uneven ultrasonic oscillation (excessive or reduced oscillation, etc.) in the booster 100 130) also provides a role to alleviate ultrasonic oscillations with non-uniform characteristics.

As such, a booster having a support 130 and a flange 1 and a packing 2 coupled thereto is also referred to as a booster combination.

However, such a booster combination accompanying the flange (1) is easily worn or damaged by the flange (1) and the packing (2) due to high ultrasonic vibration and high heat, as well as the flange (1) is the support of the booster (100) ( 130), there is a possibility that it can be easily separated from the product, resulting in a problem of deteriorating durability. In addition, there is a concern that the ultrasonic energy is damaged by the flange 1 and thus high vibration cannot be properly transmitted to the mounting object.

According to International Publication No. WO 2014/017460, a flange is placed on an ultrasonic vibrating body equipped with a tool, and one side of the flange is engaged by contacting the flange support surface formed on a separately prepared fixture while applying stress It is described that an ultrasonic vibrator assembly having a supporting structure is proposed to reduce the leakage of ultrasonic energy generated from the vibrator to a flange, etc., so that higher vibration energy can be delivered to a processing object, that is, a tool.

However, since this structure is also a structure that connects the vibrator and the booster through the flange, it has the problem of deteriorating the durability of the coupling structure itself by the flange from vibration and high heat generated by the vibration energy. Even if the flange is a separate component from the booster, there is a disadvantage that vibration energy may leak due to the gap between the flange.

Therefore, there is a need to develop a booster for an ultrasonic vibrator module that can deliver uniform and excellent ultrasonic vibration energy to the mounting object as well as maintaining the coupling force with the wall of the mounting object based on the integral structure without the flange.

The present invention was conceived to overcome the problems of the above technology, and preventing the loss of ultrasonic vibration energy by integrally mounting a separate physical means in a state in which the flange and packing are removed from the booster, which is a component of the ultrasonic vibrator module. Of course, the main purpose is to provide a booster that can reduce the hassle of replacing flanges and packings.

Another object of the present invention is to selectively provide a support coupling portion or a body coupling portion to match each booster structure by dividing the structure of the booster according to the presence or absence of the support.

Still another object of the present invention is to provide a means for enhancing amplification in a booster without a support and a structure of a body coupling part linked to the means.

In order to achieve the above object, a first embodiment of an integrated booster for an ultrasonic vibrator module according to the present invention includes a first body on the vibrator side, a second body on the horn side with a diameter smaller than that of the first body, and the In the booster for an ultrasonic vibrator module comprising a support formed protruding along the periphery of the boundary portions of the first and second main bodies, and a flange and packing coupled along the periphery of the upper surface of the support, wherein the flange and the packing are removed, the support It characterized in that it comprises a; has a larger diameter than the support along the upper surface of the support and is integrally coupled to the support.

In addition, a first embodiment of the integrated booster for an ultrasonic vibrator module according to the present invention includes a first body on the vibrator side, a second body on the horn side, and a lower portion of the second body, having a diameter smaller than that of the first body. A booster for an ultrasonic vibrator module comprising a flange and a packing coupled along a side circumference, wherein the flange and the packing are removed, and a main body integrally combined with a diameter larger than the first body along the circumference of the first body It characterized in that it includes; coupling portion.

According to the integrated booster for an ultrasonic vibrator module according to the present invention,

1) It can prevent unnecessary and troublesome replacement of parts while preventing loss of ultrasonic vibration energy,

2) By providing a specialized integrated structure according to the presence or absence of a support, it is possible to obtain the above-described effect universally.

3) Not only can it reinforce the stable coupling relationship with the wall of the installation target,

4) It has the effect of providing amplification performance as well as uniformity of ultrasonic vibration energy by presenting various blocks.

1 is an assembly view and an exploded perspective view showing a detailed structure of a conventional ultrasonic vibrator module.
2 is an exploded perspective view showing a detailed structure of the booster in FIG. 1.
3 is an exploded perspective view showing the detailed structure of the vibrator module including the first embodiment of the booster of the present invention.
Figure 4 is a perspective view, a front view and a cross-sectional view of a first embodiment of the booster of the present invention.
5 is a perspective view and a front view and a cross-sectional view of a second embodiment of the booster of the present invention.
6 is a partially enlarged cross-sectional view of the cutting prevention block of the first and second extension parts of FIG. 5.
7 is a partially enlarged cross-sectional view of a uniform processing block formed at a bent portion of the first and second extension parts of FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The accompanying drawings are not drawn to scale, and the same reference numerals in each drawing refer to the same components.

First, the booster 100 of the present invention is largely divided into two embodiments, the first embodiment relates to a booster 100 including a support 130, and the second embodiment is a booster 100 not including a support. It is about.

An important point is that both of the first and second embodiments of the booster 100 of the present invention do not have a flange 1 and a packing 2, and have a common point that an integral coupling means capable of efficiently replacing them is provided. will be.

Hereinafter, a first embodiment of the booster 100 of the present invention will be described with reference to FIGS. 3 and 4 and a second embodiment of the booster 100 of the present invention through FIGS. 5 to 7.

In the present invention, terms indicating directions such as'upper','lower','upper surface', and'bottom' appear, which are in accordance with a direction set based on the attached drawing, for example, in FIG. The'upper' of 100) means the upper part of the booster 100 toward the horn 20, and the'upper surface' of the support 130 is understood as indicating the upper surface of the support 130 I can.

3 is an exploded perspective view showing a detailed structure of a vibrator module including a first embodiment of the booster of the present invention, and FIG. 4 is a perspective view and a front view and a cross-sectional view of the first embodiment of the booster of the present invention. Specifically, in FIG. 4, FIG. 4(a) is a perspective view, FIG. 4(b) is a front view, and FIG. 4(c) is a cross-sectional view.

First, a schematic structure of the booster 100 according to FIGS. 3 to 4 will be described. The booster 100 according to FIGS. 3 and 4 includes a first body 110 and a horn 20 facing the vibrator 10. The second main body 120 having a smaller diameter than the first main body 110 and protruding from the boundary of the first and second main bodies 110 and 120 along the periphery of the boundary of the first and second bodies 110 and 120 It includes a formed support (130).

As can be seen from Figures 3 and 4, the vibrator module including the first embodiment of the booster 100 of the present invention is a booster 100 without a flange (including packing) that is coupled to each of the upper and lower surfaces of the support 130 Are presented.

That is, the booster 100 according to FIGS. 3 and 4 has a larger diameter than the support 130 along the circumference of the upper surface of the support 130 instead of a known flange and is integrally coupled to the support 130 It has 200.

The supporter coupling portion 200 is integrally coupled to the supporter 130, that is, after each manufacture, it is not coupled by adhesives or fasteners, but is integrally coupled when the supporter 130 is manufactured through a mold ( one body).

When the support coupling part 200 is integrally coupled to the upper surface of the support 130, as mentioned above, the ultrasonic vibration energy is prevented from being unevenly generated in the support 130, as well as replacement of the flange and packing. It is possible to perform a function that can eliminate the hassle of performing periodic operation.

In addition, it prevents the occurrence of defects due to the accumulation of fatigue of the packing and the horizontal deviation due to aging, and also prevents the problem of loss of ultrasonic vibration energy due to damage to the coupling surface when the booster 100 and the vibrator are combined. I can. In addition, since the ultrasonic vibration energy is not lost through the flange, excellent and high ultrasonic vibration energy can be transmitted to the mounting object and the lifespan can be remarkably increased.

In addition, the support coupling portion 200 may replace a function of the existing flange that provides a coupling relationship between the mounting object, for example, when the diameter of the support 130 and the diameter of the through hole of the mounting object are the same When the first body 110 is inserted into the through hole formed in the wall of the target, the support 130 is in contact with the inner wall of the through hole, and the support coupling part 200 is seated on the upper surface of the wall of the target, and the booster 100 is Prevents exiting through holes. In addition, if the diameter of the support coupling portion 200 is larger than the through hole, the same function may be performed even when the diameter of the through hole is larger than the diameter of the support 130.

That is, the support coupling unit 200 may provide a basis for coupling the booster 100 to the mounting object by performing a function such as a locking action or a stepped through hole formed in the wall of the mounting object. When a solid coupling relationship between the part 200 and the wall to be mounted is required, it is of course possible to attach or fasten the portion around the upper surface of the through hole through a separate adhesive means or a few fasteners.

Additionally, the support coupling part 200 may be formed of a standing part 210 and a bent part 220.

The standing part 210 is a part that is erected from the side end of the support 130 toward the horn 20 side, and the bent part 220 is a part that is bent and extended outward from the upper side of the standing part 210 do.

According to the structure of the standing part 210 and the bent part 220, the support coupling part 200 is erected on the upper surface of the circumferential portion of the support 130, that is, the side end, and then bent outward from the upper side of the standing portion. Since the structure is provided, the space 101 is generated between the first and second main bodies 110 and 120 due to the structure of the support 130 while faithfully providing the same role as the stepped step described above, and amplifying the ultrasonic vibration energy, that is, the space 101 It is possible to further expand the volume of the booster 100 provides a characteristic capable of enhancing the boosting function for ultrasonic vibration energy.

In addition, a recessed groove 230 recessed between the upper and lower portions of the outer peripheral surface (ie, the outer surface) of the bent part 220 is formed to extend along the periphery of the outer peripheral surface of the bent part 220.

The recessed groove 230 provides a basis for coupling the support coupling portion 200 itself to the inner wall of the through hole penetrating the wall of the mounting target, in other words, the diameter of the support coupling portion 200 and the When the diameter is the same, the support coupling part 200 may be positioned on the upper surface of the through hole, for example, and then the recessed groove 230 may be fitted to the inner wall of the through hole by applying some external force.

For this reason, it is possible to perform a role that can be firmly coupled without any other adhesive means when the support coupling portion 200 is coupled to the wall of the mounting object.

In summary, the basic structure and improved structure of the supporter coupling part 200 integrally formed on the upper surface of the supporter 130 of the booster 100 provides a reliable ultrasonic vibration energy conservation function compared to the existing flange/packing combination structure. In addition, it may have a characteristic capable of providing a bonding force to the wall of the mounting object.

5 is a perspective view, a front view and a cross-sectional view of a second embodiment of the booster of the present invention. That is, FIG. 5(a) is a perspective view, FIG. 5(b) is a front view, and FIG. 5(c) is a cross-sectional view.

The booster 100 according to FIG. 5 relates to a structure without the support 130 in the booster 100 of FIGS. 3 and 4, and is specifically, one side of the first body 110, specifically, of the first body 110. A body coupling portion 300 integrally coupled while having a diameter larger than the diameter of the first body 110 is provided along the periphery of the lower side (vibrator side).

The main body coupling part 300 provides a stepped-like function that can be coupled to the wall of the mounting target, like the existing support 130, while preventing the loss of ultrasonic vibration energy as in the booster 100 of FIGS. 3 and 4 It provides properties that can retain the same effects as guaranteeing durability.

The body coupling part 300 may also have a recessed groove 310 extending along the circumference between the upper and lower portions of the outer circumferential surface, and thus the recessed groove 230 of the first embodiment of the booster 100 and Likewise, by being fitted to the wall of the mounting object, it can perform the same role as a medium that can be firmly coupled to the mounting object.

Additionally, the first body 110 of the booster 100 may include a first extension part 111 and a second extension part 111.

The first extended part 111 is a part extending outward (outward) from the upper outer circumferential surface, which is a boundary part with the second body 120, that is, a horizontally extended part, and the second extended part 112 is a first extended part 111 ) Is bent at the end of the first body 110 and extends parallel to the outer peripheral surface of the first body 110 to a point before reaching the lower end of the first body 110.

According to the structure of the first and second extension parts 111 and 112, a gap is generated between the second extension part 112 and the outer peripheral surface of the first body 111, which is referred to as an amplification space 113. The lower side of the amplification space 113 is basically open, and the lower side is closed with a cover (for example, a cover) made of a separate thin layer (thin layer) to further reduce the ultrasonic vibration energy by the body coupling part 300. It is also possible to deliver without loss.

In this case, the body coupling part 300 described above is formed along the circumference of the outer peripheral surface of the end side of the second extension part 112.

According to this structure, the booster 100 according to FIG. 5 does not have the same space 101 as in the booster 100 of FIGS. 3 and 4 because there is no support 130 unlike the booster 100 of FIGS. 3 and 4. There may be an insufficient aspect to enhance the boosting function of the ultrasonic vibration energy, and the boosting function of the ultrasonic vibration energy can be achieved by the amplification space 113.

At the same time, the body coupling part 300 is integrally coupled to the second extension part 112 located at the end side of the amplification space 130 to fully utilize the internal space of the amplification space 130 to reduce the amplified ultrasonic vibration energy. It can be transmitted to the mounting object without loss, and as a result, ultrasonic vibration energy can be enhanced.

In addition, when the body coupling unit 300 is directly coupled to the first body 110, such as a phenomenon in which the ultrasonic vibration energy may have excessive/uneven characteristics in the support 130 described above, the ultrasonic vibration energy is excessive/uneven It is possible to provide a basis for more stably transmitting ultrasonic vibration energy to the mounting object by uniformly processing what may have the amplification space 130.

6 is a partially enlarged cross-sectional view of the cutting prevention block of the first and second extension parts of FIG. 5.

6 is an enlarged view of the boundary portions of the first and second extension parts 111 and 112 on the right side in FIG. 5(c). As can be seen from FIG. 6, the second extension part 112 includes a cutting prevention block 140 It can be seen that this was formed.

Specifically, the cut prevention block 140 includes a first round section 141 extending downward from an upper outer surface of the second extension part to a first radius of curvature, and an end of the first round section 141 (in FIG. 6 ). At the point indicated by a dot) with a second radius of curvature smaller than the first round section 141, which is the lower point of the bending portion of the first and second extended parts 111 and 112 (ie, the lower side of the point connecting the first extended part). It consists of a second round section 142 extending to one side of the second extension part 112.

The cutting prevention block 140 thickens one portion of the second extension part 112 so that the bending portions of the first and second extension parts 111 and 112 are prevented from easily cutting due to the ultrasonic vibration energy. As a specific portion of the extension part 112 is thickened, it naturally prevents the ultrasonic vibration energy from being unnecessarily concentrated or having excessive characteristics.

In other words, the first round section 141 and the second round section 142 are not sharp and have a smooth round shape as a whole, but there is a difference in radius of curvature between them, so that the cutting prevention block 140 as a whole is By having a shape oriented in a diagonal direction, even if the ultrasonic vibration energy is concentrated due to the hanging cut prevention block 140, this energy is distributed in a diagonal direction above the outer side so that the uniformity of the ultrasonic vibration energy can be maintained as much as possible. I did it.

7 is a partially enlarged cross-sectional view of a second embodiment of a bent portion of the first and second extension parts of FIG. 5.

FIG. 7 also shows an enlarged view of the boundary portions of the first and second extended parts 111 and 112 on the right in FIG. 5(c), but is enlarged at a greater magnification than that of FIG. 6.

As can be seen from FIG. 7, the boundary portions of the first and second extended parts 111 and 112 are subjected to a rounding chamfer treatment. Here, a chamfer refers to a portion made by cutting the corners of a member having each cross-section, and may have many types, such as a flat surface as well as a round surface, among which the'rounding chamfer means in the present invention. 'Processing' means chamfering the edges of the boundary portions of the first and second extended parts 111 and 112 to have a rounded shape.

As described above, the reason for the rounding chamfer treatment of the boundary portions of the first and second extended parts 111 and 112 (both outside and inside) is that ultrasonic vibration energy is concentrated at the boundary portions of the first and second extended parts 111 and 112, so that the This is to prevent problems that are easily damaged. In other words, if the boundary portions of the first and second extension parts 111 and 112 are angled or sharp, the ultrasonic vibration energy may have unnecessary peak characteristics at this region. Therefore, the ultrasonic vibration energy is excessive by rounding them so that they are not angular. It was to prevent the phenomenon of concentration in advance.

Furthermore, it is possible to additionally provide a uniform processing block 150 at the boundary portion of the first and second extended parts 111 and 112, that is, inside the bent portion 114.

That is, the bent portion 114 of the first and second extension parts 111 and 112 according to FIG. 7 has a structure in which the inner and outer bent portions 114a and 114b are bent and extended with the same width while maintaining the same radius of curvature. In the based state, a uniform processing block 150 may be additionally provided on the inner bent portion 114a of the bent portion 114. Hereinafter, the bending portions of the first and second extension parts 111 and 112 are reduced and referred to as'bending portions' 114.

The uniform processing block 150 is provided in the inner bent portion 114a of the bent portion 114, and specifically includes a first rounding section 151, a second rounding section 152, and a third rounding section 153. Done.

The first rounding section 151 is a first radius of curvature (here, the first radius of curvature) from the bending start point of the second extended part side 112 to the point where it meets the virtual line extending in the normal direction from the center of the bent part 114 Is different from the first radius of curvature in FIG. 6). The second rounding section 152 has a second radius of curvature equal to the radius of curvature from the point where the virtual line meets the virtual line among the outer bent portions 114b of the first and second extension parts 111 and 112 to a point extending toward the first extension part 112. As a radius of curvature, it is a portion extending in a direction from the end of the first rounding section 151 toward the first extension part 111 side. The third rounding section 153 is a portion that is bent at the end of the second rounding section 152 and extends with a third radius of curvature to the end of the bending end of the first extended part 111 side.

The first rounding section 151 refers to an introduction portion for gradually increasing the thickness of the uniform processing block 150 as the extension proceeds from the bending start point on the side of the second extended part 112.

The second rounding section 152 is separated from the inner bent portion 114a by the first rounding section 151 and extends toward the first extended part 111 at a point where it meets the virtual line among the outer bent portions 114b. By bending and extending to the same radius of curvature as the radius of curvature up to a point, as a result, it is possible to maintain the increased bending thickness spaced apart by the first rounding section 151.

In other words, the second rounding section 152 is a portion thicker than the start portion of the first rounding section 151, and this causes a difference in the distance of the ultrasonic vibration energy transmitted to the first and second rounding sections 151 and 152. As a result, since the second rounding section 152 is thicker than the first rounding section 151, the ultrasonic vibration energy is transmitted to the second rounding section 152 earlier than the first rounding section 151.

As such, the ultrasonic vibration energy transmitted to the second rounding section 152 is reflected in the direction of the first extension part 111 on the opposite side by the inherent shape of the second rounding section 152 bent concave and extends the first on the opposite side. The reflective force may converge in a specific area of the part 111 or a direction toward the part 111. However, since the first extension part 111 is shorter in length than the second extension part 112, the second extension is likely to cause the density concentration of ultrasonic vibration energy for each unit area by adjusting the curvature of the bent part 114. It can be said to be larger than part 112. Therefore, the second rounding section 152 guides the reflective force generated when the ultrasonic vibration energy hits the rounding chamfered portion (bending portion) of the first and second extension parts 111 and 112 to converge to the opposite side, but the opposite The side is formed toward the side of the second extended part 112 which is relatively longer than the side of the first extended part 111.

In the process of controlling the reflection direction in which the ultrasonic vibration energy is reflected, the problem that the ultrasonic vibration energy is attenuated while contacting the inner wall of the bent portion 114 of the first and second extension parts 111 and 112 is reduced. It can provide a basis for vibrational energy to be transmitted without loss.

Furthermore, by having a function of distributing the pressure applied to the first extended part 111 by allowing more ultrasonic vibration energy to be transmitted to the relatively thicker second rounding section 152, the first and second extended parts 111 and 112 ), it is possible to prevent the problem that the first and second extension parts 111 and 112 are easily damaged by ensuring structural stability and durability.

The third rounding section 153 is naturally extended to be in contact with the inner bent portion 114a as shown in FIG. 8, but further, the inner bent portion 114a and the stepped jaw are not generated by a chamfer treatment. It is also possible to become.

The third rounding section 153 induces or guides the above-described reflective force in the direction of the second extended part 112 on the opposite side by bending the second rounding section 152 to be convexly bent unlike the concave bent. Can perform the function In other words, unlike the second rounding section 152, the third rounding section 153 guides the ultrasonic vibration energy to be reflected in the direction of the second extended part 112 on the opposite side, so that the rounding chamfer of the first and second extended parts 111 and 112 The ultrasonic vibration energy delivered to the processed bent portion 114 is not concentrated on the first extended part 111 and is appropriately distributed in the direction of the second extended part 112, thereby reducing the entire internal space of the amplification space 113. While fully utilized, it provides a driving force that allows ultrasonic vibration energy to be uniformly processed without being concentrated in a specific area.

In summary, the uniform processing block 150 distributes the pressure generated when the ultrasonic vibration energy impinges on the inside of the bent portion 114 of the first and second extended parts 111 and 112 to the side of the second extended part 112 ,In addition to providing a function of reinforcing structural stability and durability for the boundary of the 2 extension parts 111 and 112, the intentional first extension part 111 and the second extension by the second and third rounding sections 152 and 153 A function of inducing reflection to the part 112 provides a characteristic of uniformly amplifying ultrasonic vibration energy while using the internal space of the amplifying space 113 more widely.

As described so far, the configuration and operation of the integrated booster for an ultrasonic vibrator module according to the present invention has been expressed in the above description and drawings, but these are only described as examples, and the spirit of the present invention is not limited to the above description and drawings, It goes without saying that various changes and changes can be made without departing from the technical spirit of the present invention.

1: flange 2: packing
10: oscillator 20: horn
100: booster 101: space
110: first body 111: first extension part
112: second extension part 113: amplification space
114: bending portion 114a: inner bending portion
114b: outer bent portion 120: second body
130: support 140: cut prevention block
141: first round section 142: second round section
150: uniform processing block 151: first rounding section
152: second rounding section 153: second rounding section
200: support coupling portion 210: standing part
220: bending part 230: recessed groove
300: body coupling portion 310: recessed groove

Claims (9)

delete delete delete In the booster for an ultrasonic vibrator module comprising a first body on the vibrator side and a second body on the horn side with a diameter smaller than that of the first body,
Including; a body coupling portion integrally coupled to a larger diameter than the first body along the circumference of the first body;
The first body,
A first extension part extending outward from an outer circumferential surface of the boundary with the first body, and extending parallel to the outer circumferential surface of the first body until it is bent at an end of the first extension part and reaches the end of the first body. And an amplification space generated between the second extension part and the outer peripheral surface of the first body,
The body coupling portion is formed along the circumference of the outer peripheral surface of the end side of the second extension part,
The second extension part,
The first and second round sections extending downward from the upper outer surface of the second extension part to a first radius of curvature, and a second radius of curvature smaller than the first round section at an end of the first round section. An integrated booster for an ultrasonic vibrator module comprising a; cutting prevention block consisting of a second round section extending to one side of the second extension part, which is a point below the bent portion of the extension part. The method of claim 4,
On the outer peripheral surface of the main body coupling portion,
An integrated booster for an ultrasonic vibrator module, characterized in that a recessed groove extending along the outer circumferential surface is formed while a portion between the upper and lower portions is recessed. The method of claim 4,
The bending portion of the first and second extension parts,
An integrated booster for an ultrasonic vibrator module, characterized in that a rounding chamfer is processed. The method of claim 6,
Inside the bent portion of the first and second extension parts,
A first rounding section extending in a first radius of curvature from a bending start point of the second extended part side to a point meeting a virtual line extending in a normal direction from the center of the bent portion,
A second radius of curvature equal to a radius of curvature from a point where it meets the virtual line from the outside of the bent portion to a point extending toward the first extension part, in a direction from the end of the first rounding section toward the first extension part. An extended second rounding section, and
A uniform processing block consisting of a third rounding section that is bent at an end of the second rounding section and extends with a third radius of curvature to a bending end point of the first extended part side; characterized in that the ultrasonic vibrator module is further provided. For all-in-one booster. delete delete

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